/*
  OrangutanBuzzer.h - Library for controlling the buzzer on the Orangutan LV,
    SV, SVP, or 3pi robot. This library uses a timer1 PWM to generate the note
	frequencies and timer1 overflow interrupt to time the duration of the
	notes, so the buzzer can be playing a melody in the background while
	the rest of your code executes. This library relies on Timer1, so it will
	conflict with any other libraries that use Timer1 (e.g. OrangutanServos).
	You cannot use the OrangutanServos library to control servos while using
	the OrangutanBuzzer library to play music.
*/

/*
 * Written by Ben Schmidel et al., May 23, 2008.
 * Copyright (c) 2008-2012 Pololu Corporation. For more information, see
 *
 *   http://www.pololu.com
 *   http://forum.pololu.com
 *   http://www.pololu.com/docs/0J18
 *
 * You may freely modify and share this code, as long as you keep this
 * notice intact (including the two links above).  Licensed under the
 * Creative Commons BY-SA 3.0 license:
 *
 *   http://creativecommons.org/licenses/by-sa/3.0/
 *
 * Disclaimer: To the extent permitted by law, Pololu provides this work
 * without any warranty.  It might be defective, in which case you agree
 * to be responsible for all resulting costs and damages.
 */
 
#ifndef OrangutanBuzzer_h
#define OrangutanBuzzer_h

#include "../OrangutanResources/include/OrangutanModel.h"

#define PLAY_AUTOMATIC	0
#define PLAY_CHECK		1

//                                             n
// Equal Tempered Scale is given by f  = f  * a
//                                   n    o
//
//  where f  is chosen as A above middle C (A4) at f  = 440 Hz
//         o                                        o
//  and a is given by the twelfth root of 2 (~1.059463094359)

// key

#define NOTE_C(x)			( 0 + (x)*12)
#define NOTE_C_SHARP(x)		( 1 + (x)*12)
#define NOTE_D_FLAT(x)		( 1 + (x)*12)
#define NOTE_D(x)			( 2 + (x)*12)
#define NOTE_D_SHARP(x)		( 3 + (x)*12)
#define NOTE_E_FLAT(x)		( 3 + (x)*12)
#define NOTE_E(x)			( 4 + (x)*12)
#define NOTE_F(x)			( 5 + (x)*12)
#define NOTE_F_SHARP(x)		( 6 + (x)*12)
#define NOTE_G_FLAT(x)		( 6 + (x)*12)
#define NOTE_G(x)			( 7 + (x)*12)
#define NOTE_G_SHARP(x)		( 8 + (x)*12)
#define NOTE_A_FLAT(x)		( 8 + (x)*12)
#define NOTE_A(x)			( 9 + (x)*12)
#define NOTE_A_SHARP(x)		(10 + (x)*12)
#define NOTE_B_FLAT(x)		(10 + (x)*12)
#define NOTE_B(x)			(11 + (x)*12)

#ifndef ARDUINO // don't define these for Arduino (F() and A4 conflict)

#define C(x)			( 0 + (x)*12)
#define C_SHARP(x)		( 1 + (x)*12)
#define D_FLAT(x)		( 1 + (x)*12)
#define D(x)			( 2 + (x)*12)
#define D_SHARP(x)		( 3 + (x)*12)
#define E_FLAT(x)		( 3 + (x)*12)
#define E(x)			( 4 + (x)*12)
#define F(x)			( 5 + (x)*12)
#define F_SHARP(x)		( 6 + (x)*12)
#define G_FLAT(x)		( 6 + (x)*12)
#define G(x)			( 7 + (x)*12)
#define G_SHARP(x)		( 8 + (x)*12)
#define A_FLAT(x)		( 8 + (x)*12)
#define A(x)			( 9 + (x)*12)
#define A_SHARP(x)		(10 + (x)*12)
#define B_FLAT(x)		(10 + (x)*12)
#define B(x)			(11 + (x)*12)

// special notes
#define A4				A(4)			// center of the Equal-Tempered Scale

#endif

#define SILENT_NOTE		0xFF			// this note will silence the buzzer

#define DIV_BY_10		(1 << 15)		// frequency bit that indicates Hz/10


#if defined(_ORANGUTAN_SVP) || defined(_ORANGUTAN_X2)

#define BUZZER_DDR		DDRD
#define BUZZER			(1 << PORTD4)
#define BUZZER_IO		IO_D4

#else

#define BUZZER_DDR		DDRB
#define BUZZER			(1 << PORTB2)
#define BUZZER_IO		IO_B2

#endif

#ifdef __cplusplus

class OrangutanBuzzer
{
  public:

    // constructor
	OrangutanBuzzer();

	// Sets up timer 1 to play the desired frequency (in Hz or .1 Hz) for the
	// the desired duration (in ms). Allowed frequencies are 40 Hz to 10 kHz.
	// 'volume' controls buzzer volume, with 15 being loudest and 0 being 
	// quietest.  If the most significant bit of 'freq' is set, the frequency
	// is taken to be the value of the lower 15 bits in units of .1 Hz.
	// Otherwise the units are in Hz.
	// Note: frequency*duration/1000 must be less than 0xFFFF (65535).  This
	// means that you can't use a max duration of 65535 ms for frequencies
	// greater than 1 kHz.  For example, the max duration you can use for a
	// frequency of 10 kHz is 6553 ms.  If you use a duration longer than this,
	// you will cause an integer overflow that produces unexpected behavior.
	static void playFrequency(unsigned int freq, unsigned int duration, 
				   	   unsigned char volume);
	
	// Sets up timer 1 to play the desired note for the desired duration
	// (in ms).  'volume' controls the buzzer volume, with 15 being loudest and
	// 0 being quietest.
	// note = key + octave * 12, where 0 <= key < 12
	// example: A4 = A + 4 * 12, where A = 9 (so A4 = 57)
	// A note is converted to a frequency by the formula:
	//   Freq(n) = Freq(0) * a^n
	// where
	//   Freq(0) is chosen as A4, which is 440 Hz
	// and
	//   a = 2 ^ (1/12)
	// n is the number of notes you are away from A4.
	// if note = 16, freq = 41.2 Hz (E1 - lower limit as freq must be >40 Hz)
	// if note = 57, freq = 440 Hz (A4 - central value of ET Scale)
	// if note = 111, freq = 9.96 kHz (D#9 - upper limit, freq must be <10 kHz)
	// if note = 255, freq = 1 kHz and buzzer is silent (silent note)
	static void playNote(unsigned char note, unsigned int duration,
				  unsigned char volume);

	// Plays the specified sequence of notes.  If the play mode is 
	// PLAY_AUTOMATIC, the sequence of notes will play with no further
	// action required by the user.  If the play mode is PLAY_CHECK,
	// the user will need to call playCheck() in the main loop to initiate
	// the playing of each new note in the sequence.  The play mode can
	// be changed while the sequence is playing.  
	// This is modeled after the PLAY commands in GW-BASIC, with just a
	// few differences.
	//
	// The notes are specified by the characters C, D, E, F, G, A, and
	// B, and they are played by default as "quarter notes" with a
	// length of 500 ms.  This corresponds to a tempo of 120
	// beats/min.  Other durations can be specified by putting a number
	// immediately after the note.  For example, C8 specifies C played as an
	// eighth note, with half the duration of a quarter note. The special
	// note R plays a rest (no sound).
	//
	// Various control characters alter the sound:
	//   '>' plays the next note one octave higher
	//
	//   '<' plays the next note one octave lower
	//
	//   '+' or '#' after a note raises any note one half-step
	//
	//   '-' after a note lowers any note one half-step
	//
	//   '.' after a note "dots" it, increasing the length by
	//       50%.  Each additional dot adds half as much as the
	//       previous dot, so that "A.." is 1.75 times the length of
	//       "A".
	//
	//   'O' followed by a number sets the octave (default: O4).
	//
	//   'T' followed by a number sets the tempo (default: T120).
	//
	//   'L' followed by a number sets the default note duration to
	//       the type specified by the number: 4 for quarter notes, 8
	//       for eighth notes, 16 for sixteenth notes, etc.
	//       (default: L4)
	//
	//   'V' followed by a number from 0-15 sets the music volume.
	//       (default: V15)
	//
	//   'MS' sets all subsequent notes to play staccato - each note is played
	//       for 1/2 of its allotted time, followed by an equal period
	//       of silence.
	//
	//   'ML' sets all subsequent notes to play legato - each note is played
	//       for its full length.  This is the default setting.
	//
	//   '!' resets all persistent settings to their defaults.
	//
	// The following plays a c major scale up and back down:
	//   play("L16 V8 cdefgab>cbagfedc");
	//
	// Here is an example from Bach:
	//   play("T240 L8 a gafaeada c+adaeafa <aa<bac#ada c#adaeaf4");
	static void play(const char *sequence);

	// A version of play that takes a pointer to program space instead
	// of RAM.  This is desirable since RAM is limited and the string
	// must be in program space anyway.
	static void playFromProgramSpace(const char *sequence_p);

	// This puts play() into a mode where instead of advancing to the
	// next note in the sequence automatically, it waits until the
	// function playCheck() is called. The idea is that you can
	// put playCheck() in your main loop and avoid potential
	// delays due to the note sequence being checked in the middle of
	// a time sensitive calculation.  It is recommended that you use
	// this function if you are doing anything that can't tolerate
	// being interrupted for more than a few microseconds.
	// Note that the play mode can be changed while a sequence is being
	// played.
	//
	// Usage: playMode(PLAY_AUTOMATIC) makes it automatic (the
	// default), playMode(PLAY_CHECK) sets it to a mode where you have
	// to call playCheck().
	static void playMode(unsigned char mode);

	// Checks whether it is time to start another note, and starts
	// it if so.  If it is not yet time to start the next note, this method
	// returns without doing anything.  Call this as often as possible 
	// in your main loop to avoid delays between notes in the sequence.
	//
	// Returns true if it is still playing.
	static unsigned char playCheck();

	// Returns 1 if the buzzer is currently playing, otherwise it returns 0
	static unsigned char isPlaying();
	
	// Stops all sound playback immediately.
	static void stopPlaying();
	
	
  private:
	
	// initializes timer1 for buzzer control
	static void init2();
	static void init();
};

extern "C" {
#endif // __cplusplus

void buzzer_init(void);
void play_frequency(unsigned int freq, unsigned int duration, 
		       unsigned char volume);
void play_note(unsigned char note, unsigned int duration,
		  unsigned char volume);
void play(const char *sequence);
void play_from_program_space(const char *sequence);
unsigned char is_playing(void);
void stop_playing(void);

unsigned char play_check(void);
void play_mode(unsigned char mode);

#ifdef __cplusplus
}
#endif

#endif

// Local Variables: **
// mode: C++ **
// c-basic-offset: 4 **
// tab-width: 4 **
// indent-tabs-mode: t **
// end: **
